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Wang SC, Lin CJ, Chiang SM, et al. Tailoring noise frequency spectrum between two consecutive second derivative filtering procedures to improve liquid chromatography-mass spectrometry determinations. Anal Chem. 2008;80(6):2097-104doi: 10.1021/ac702222m.
Wang, S. C., Lin, C. J., Chiang, S. M., & Yu, S. N. (2008). Tailoring noise frequency spectrum between two consecutive second derivative filtering procedures to improve liquid chromatography-mass spectrometry determinations. Analytical chemistry, 80(6), 2097-104. https://doi.org/10.1021/ac702222m
Wang, Shau-Chun, et al. "Tailoring noise frequency spectrum between two consecutive second derivative filtering procedures to improve liquid chromatography-mass spectrometry determinations." Analytical chemistry vol. 80,6 (2008): 2097-104. doi: https://doi.org/10.1021/ac702222m
Wang SC, Lin CJ, Chiang SM, Yu SN. Tailoring noise frequency spectrum between two consecutive second derivative filtering procedures to improve liquid chromatography-mass spectrometry determinations. Anal Chem. 2008 Mar 15;80(6):2097-104. doi: 10.1021/ac702222m. Epub 2008 Feb 16. PMID: 18278950.
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Anal Chem. 2008 Mar 15;80(6):2097-104. doi: 10.1021/ac702222m. Epub 2008 Feb 16.

Tailoring noise frequency spectrum between two consecutive second derivative filtering procedures to improve liquid chromatography-mass spectrometry determinations.

Analytical chemistry

Shau-Chun Wang, Chiao-Juan Lin, Shu-Min Chiang, Sung-Nien Yu

Affiliations

  1. Department of Chemistry and Biochemistry, National Chung Cheng University, 168 University Road, Min-Hsiung, Chia-Yi 621, Taiwan. [email protected]

PMID: 18278950 DOI: 10.1021/ac702222m

Abstract

This paper reports a simple chemometric technique to alter the noise spectrum of a liquid chromatography-mass spectrometry (LC-MS) chromatogram between two consecutive second-derivative filter procedures to improve the peak signal-to-noise (S/N) ratio enhancement. This technique is to multiply one second-derivative filtered LC-MS chromatogram with another artificial chromatogram added with thermal noises prior to the other second-derivative filter. Because the second-derivative filter cannot eliminate frequency components within its own filter bandwidth, more efficient peak S/N ratio improvement cannot be accomplished using consecutive second-derivative filter procedures to process LC-MS chromatograms. In contrast, when the second-derivative filtered LC-MS chromatogram is conditioned with the multiplication alteration prior to the other second-derivative filter, much better ratio improvement is achieved. The noise frequency spectrum of the second-derivative filtered chromatogram, which originally contains frequency components within the filter bandwidth, is altered to span a broader range with multiplication operation. When the frequency range of this modified noise spectrum shifts toward the other regimes, the other second-derivative filter, working as a band-pass filter, is able to provide better filtering efficiency to obtain higher peak S/N ratios. Real LC-MS chromatograms, of which 5-fold peak S/N ratio improvement achieved with two consecutive second-derivative filters remains the same S/N ratio improvement using a one-step second-derivative filter, are improved to accomplish much better ratio enhancement, approximately 25-fold or higher when the noise frequency spectrum is modified between two matched filters. The linear standard curve using the filtered LC-MS signals is validated. The filtered LC-MS signals are also more reproducible. The more accurate determinations of very low-concentration samples (S/N ratio about 5-7) are obtained via standard addition procedures using the filtered signals rather than the determinations using the original signals.

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